Treating Data Flows Differently Based on Level of Interest

ABSTRACT

A traffic manager module of a cyber threat defense platform that can differentiate between data flows to a client device. A registration module can register a connection between devices within a client network to transmit a series of data packets. A classifier module can execute a comparison of features of the connection to a set of interest criteria to determine an interest level for the cyber threat defense platform in the connection. The classifier module can apply an interest classifier describing the interest level to the connection based on the comparison. A deep packet inspection engine can examine the data packets of the connection for cyber threats if the interest classifier indicates interest. A diverter can shunt the data packets of the connection away from the deep packet inspection engine if the interest classifier indicates no interest.

RELATED APPLICATION

This application claims priority to and the benefit of under 35 USC 119 of U.S. provisional patent application titled “An Artificial Intelligence Based Cyber Security System,” filed Feb. 28, 2020, Ser. No. 62/983,307, and U.S. provisional patent application titled “An Intelligent Cyber Security System,” filed Sep. 14, 2020, Ser. No. 63/078,092, which is incorporated herein by reference in its entirety.

NOTICE OF COPYRIGHT

A portion of this disclosure contains material that is subject to copyright protection. The copyright owner has no objection to the facsimile reproduction by anyone of the material subject to copyright protection as it appears in the United States Patent & Trademark Office's patent file or records, but otherwise reserves all copyright rights whatsoever.

FIELD

Embodiments of the design provided herein generally relate to a cyber threat defense platform. In an embodiment, a cyber threat defense platform may selectively perform deep packet inspection at a client device to identify anomalous data connections.

BACKGROUND

In the cyber security environment, firewalls, endpoint security methods and other tools such as security information and event management systems (SIEMs) and restricted environments, such as sandboxes, are deployed to enforce specific policies and provide protection against certain threats. These tools currently form an important part of an organization's cyber defense strategy, but they are insufficient in the new age of cyber threat.

Cyber threat, including email threats, viruses, trojan horses, and worms, can subtly and rapidly cause harm to a network. Additionally, human users may wreak further damage to the system by malicious action. A cyber security system has to identify each of these cyber threats as they evolve.

SUMMARY

A traffic manager module of a cyber threat defense platform that can differentiate between data flows to a client device. A registration module is configured to register a connection between one or more devices within a client network to transmit a series of one or more data packets. A classifier module is configured to execute a comparison of features of the connection to a set of interest criteria to determine an interest level for the cyber threat defense platform in the connection. The classifier module is further configured to apply an interest classifier describing the interest level to the connection based on the comparison. A deep packet inspection engine is configured to examine the one or more data packets of the connection for cyber threats if the interest classifier indicates interest. A diverter is configured to shunt the one or more data packets of the connection away from the deep packet inspection engine if the interest classifier indicates no interest.

These and other features of the design provided herein can be better understood with reference to the drawings, description, and claims, all of which form the disclosure of this patent application.

DRAWINGS

The drawings refer to some embodiments of the design provided herein in which:

FIG. 1 illustrates a block diagram of an embodiment of a cyber threat defense platform with a cyber threat module that references machine-learning models that are trained on the normal behavior of a network entity to identify cyber threats by identifying deviations from normal behavior.

FIG. 2 illustrates a block diagram of an embodiment of an example chain of unusual behavior for a network entity activity in connection with the rest of the network under analysis.

FIG. 3 illustrates an example cyber threat defense platform protecting an example network.

FIG. 4 illustrates in a block diagram the integration of the threat detection system with other network protections.

FIG. 5 illustrates an application of a cyber threat defense platform using advanced machine learning to detect anomalous behavior.

FIG. 6 illustrates a flowchart of an embodiment of a method for modeling human, machine or other activity.

FIG. 7 illustrates a flowchart of an embodiment of a method for identifying a cyber threat.

FIG. 8 illustrates third-party event data.

FIG. 9 illustrates a flowchart of an embodiment of a method for pulling data from an online application.

FIG. 10 illustrates a flowchart of an embodiment of a method for identifying an autonomous response.

FIG. 11 illustrates a block diagram of a threat risk parameter.

FIG. 12 illustrates a flowchart of an embodiment of a method for generating a threat risk parameter.

FIG. 13 illustrates a block diagram of a benchmark matrix.

FIG. 14 illustrates a flowchart of an embodiment of a method for generating a benchmark matrix.

FIG. 15 illustrates a block diagram of a physical traffic manager module.

FIG. 16 illustrates a block diagram of a virtual traffic manager module.

FIG. 17 illustrates a flowchart of an embodiment of a method for establishing interesting criteria.

FIG. 18 illustrates a flowchart of an embodiment of a method for processing a data connection with a deep packet inspection engine.

FIG. 19 illustrates a flowchart of an embodiment of a method for shunting a data connection past a deep packet inspection engine.

FIG. 20 illustrates a flowchart of an embodiment of a method for processing a data connection with a dropped data packet.

FIG. 21 illustrates a flowchart of an embodiment of a method for handling data connections during an anomalous event.

FIG. 22 illustrates a flowchart of an embodiment of a method for using host-based decryption for data connections on client devices.

FIG. 23 illustrates a flowchart of an embodiment of a method for offsite storage of packet capture from data connections to client devices.

FIG. 24 illustrates an example network to be protected by the cyber threat defense platform.

While the design is subject to various modifications, equivalents, and alternative forms, specific embodiments thereof have been shown by way of example in the drawings and will now be described in detail. It should be understood that the design is not limited to the particular embodiments disclosed, but—on the contrary—the intention is to cover all modifications, equivalents, and alternative forms using the specific embodiments.

DESCRIPTION

In the following description, numerous specific details are set forth, such as examples of specific data signals, named components, number of servers in a system, etc., in order to provide a thorough understanding of the present design. It will be apparent, however, to one of ordinary skill in the art that the present design can be practiced without these specific details. In other instances, well known components or methods have not been described in detail but rather in a block diagram in order to avoid unnecessarily obscuring the present design. Further, specific numeric references such as a first server, can be made. However, the specific numeric reference should not be interpreted as a literal sequential order but rather interpreted that the first server is different than a second server. Thus, the specific details set forth are merely exemplary. Also, the features implemented in one embodiment may be implemented in another embodiment where logically possible. The specific details can be varied from and still be contemplated to be within the spirit and scope of the present design. The term coupled is defined as meaning connected either directly to the component or indirectly to the component through another component.

In general, the cyber threat defense platform may use artificial intelligence to analyze cyber security threats. FIG. 1 illustrates a block diagram of an embodiment of a cyber threat defense platform with a cyber threat module that references machine learning models that are trained on the normal behavior of network activity and user activity associated with a network. The cyber threat module determines a threat risk parameter that factors in ‘what is a likelihood of a chain of one or more unusual behaviors of email activity, network activity, and user activity under analysis that fall outside of being a normal benign behavior;’ and thus, are likely malicious behavior.

The cyber threat defense platform 100 may protect against cyber security threats from an e-mail system as well as its network. The cyber threat defense platform 100 may include components such as i) a trigger module, ii) a gather module, iii) a data store, iv) a network module, v) an email module, vi) a coordinator module, vii) a comparison module, viii) a cyber threat module, ix) a traffic manager module, x) a user interface module, xi) an analyzer module, xii) an autonomous response module, xiii) at least one input or output (I/O) port to securely connect to other ports as required, xiv) one or more machine learning models such as a first Artificial Intelligence model trained on characteristics of vectors for malicious activity and related data, a second Artificial Intelligence model trained on email, a third Artificial Intelligence model trained on potential cyber threats, a fourth Artificial Intelligence model trained on a normal pattern of life, and one or more Artificial Intelligence models each trained on different users, devices, system activities and interactions between entities in the system, and other aspects of the system, as well as xv) other similar components in the cyber threat defense platform.

A trigger module may detect time stamped data indicating one or more i) events and/or ii) alerts from I) unusual or II) suspicious behavior/activity are occurring and then triggers that something unusual is happening. Accordingly, the gather module is triggered by specific events and/or alerts of i) an abnormal behavior, ii) a suspicious activity, and iii) any combination of both. The inline data may be gathered on the deployment from a data store when the traffic is observed. The scope and wide variation of data available in this location results in good quality data for analysis. The collected data is passed to the comparison module and the cyber threat module.

The gather module may comprise of multiple automatic data gatherers that each look at different aspects of the data depending on the particular hypothesis formed for the analyzed event and/or alert. The data relevant to each type of possible hypothesis will be automatically pulled from additional external and internal sources. Some data is pulled or retrieved by the gather module for each possible hypothesis. A feedback loop of cooperation occurs between the gather module, a probe module monitoring network and email activity, the comparison module to apply one or more models trained on different aspects of this process, and the cyber threat module to identify cyber threats based on comparisons by the comparison module. While an email module is mentioned, a similar module may be applied to other communication systems, such as text messaging and other possible vectors for malicious activity. Each hypothesis of typical threats can have various supporting points of data and other metrics associated with that possible threat, such as a human user insider attack, inappropriate network behavior, or email behavior or malicious software or malware attack, inappropriate network behavior, or email behavior. A machine-learning algorithm will look at the relevant points of data to support or refute that particular hypothesis of what the suspicious activity or abnormal behavior related for each hypothesis on what the suspicious activity or abnormal behavior relates to. Networks have a wealth of data and metrics that may be collected. The gatherers may then filter or condense the mass of data down into the important or salient features of data. In an embodiment, the network module, the email module, and the coordinator module may be portions of the cyber threat module.

A probe module can be configured to collect probe data from a probe deployed to a client device. The client device is a device operated by a user to interact with the network. The probe data describes any activity executed by the client device and administrated by a network administrator associated with the network. A network-administrated activity may be network activity or email activity. Further, the probe module may be divided into an email module and a network module. The probe module can be configured to collect, from one or more probes deployed to one or more network devices, input data describing network-administrated activity executed by a client device.

The network module monitoring network-administrated activity and the email module monitoring email may each feed their data to a coordinator module to correlate causal links between these activities to supply this input into the cyber threat module. The coordinator module can be configured to contextualize the network data and the email data to create a combined data set for analysis.

The cyber threat module may also use one or more machine-learning models trained on cyber threats in the network. The cyber threat module may reference the models that are trained on the normal behavior of user activity, network activity, and email activity associated with the network. The cyber threat module can reference these various trained machine-learning models and data from the network module, the email module, and the trigger module. The cyber threat module can determine a threat risk parameter that factors in how the chain of unusual behaviors correlate to potential cyber threats and ‘what is a likelihood of this chain of one or more unusual behaviors of the network activity and user activity under analysis that fall outside of being a normal benign behavior;’ and thus, is malicious behavior.

The one or more machine learning models can be self-learning models using unsupervised learning and trained on a normal behavior of different aspects of the system, for example, device activity and user activity associated with email. The self-learning models of normal behavior are regularly updated. The self-learning model of normal behavior is updated when new input data is received that is deemed within the limits of normal behavior. A normal behavior threshold is used by the model as a moving benchmark of parameters that correspond to a normal pattern of life for the computing system. The normal behavior threshold is varied according to the updated changes in the computer system allowing the model to spot behavior on the computing system that falls outside the parameters set by the moving benchmark.

The comparison module can compare the analyzed metrics on the user activity and network activity compared to their respective moving benchmark of parameters that correspond to the normal pattern of life for the computing system used by the self-learning machine-learning models and the corresponding potential cyber threats.

The comparison module is configured to execute a comparison of input data to at least one machine-learning model to spot behavior on the network deviating from a normal benign behavior of that network entity. The comparison module receives the combined data set from the coordinator module. The at least one machine-learning model is trained on a normal benign behavior of a network entity. The at least one machine uses a normal behavior benchmark describing parameters corresponding to a normal pattern of activity for that network entity. The comparison module can use the comparison to identify whether the network entity is in a breach state of the normal behavior benchmark.

The comparison module can be integrated with the cyber threat module. The cyber threat defense platform 100 may also include one or more machine-learning models trained on gaining an understanding of a plurality of characteristics on a transmission and related data including classifying the properties of the transmission and its meta data. The cyber threat module can then determine, in accordance with the analyzed metrics and the moving benchmark of what is considered normal behavior, a cyber-threat risk parameter indicative of a likelihood of a cyber-threat.

The cyber threat module can also reference the machine learning models trained on a network event and related data to determine if a network event or a series of network events under analysis have potentially malicious characteristics. The cyber threat module can also factor this network event characteristics analysis into its determination of the threat risk parameter. The cyber threat module can generate a set of incident data describing an anomalous event by an entity, here representing a user or a device participating in the network. The cyber threat module can use the incident data to determine whether the anomalous event indicates a breach state representing a malicious incident or confidential data exposure. To do this, the cyber threat module can use the user interface and display module to present the incident data to a user analyst for review. Alternately, the cyber threat module can execute an autonomous analyst to use machine learning to determine whether the entity has entered a breach state.

The cyber threat defense platform 100 may also include one or more machine learning models trained on gaining an understanding of a plurality of characteristics on a SaaS administrative event and related data including classifying the properties of the SaaS administrative event and its meta data.

Alternately, the cyber threat module can execute an autonomous analyst to use machine-learning to determine whether the network entity in the breach state is a cyber threat. The cyber threat module is configured to identify whether the breach state identified by the comparison module and a chain of relevant behavioral parameters deviating from the normal benign behavior of that network entity correspond to a cyber threat.

The cyber threat defense platform 100 may use multiple machine learning models. Each machine learning model may be trained on specific aspects of the normal pattern of life for the system such as devices, users, network traffic flow, outputs from one or more cyber security analysis tools analyzing the system, and others. One or more machine learning models may also be trained on characteristics and aspects of all manner of types of cyber threats. One or more machine learning models may also be trained by observing vectors for malicious activity, such as network activity or emails.

The cyber threat defense platform 100 may have a traffic manager module to differentiate between data flows to determine which data flow to examine. The data flows are connection to one or more devices in a physical or virtualized client network transferring a series of one or more data packets. The traffic manager module can be in a host-based agent in the client network, such as on a laptop used in the client network. Alternately, the traffic manager module can be in a virtualized sensor installed as a standalone virtual machine or onto on a hypervisor which receives packets via spans or traffic mirroring. Further, the traffic manager module can be in a centralized cyber security appliance, which may be physical or virtual. The cyber threat defense platform can both receive packet data itself via spans or traffic mirroring while in communication with any host-based agents and a virtual sensor probe.

The cyber threat defense platform 100 may supplement the data provided to the users and cyber professionals using an analyzer module to monitor the various connections between client devices in the network. The analyzer module can flag a client device that is the site of an anomalous event. The analyzer module can be configured to flag a client device for host-based traffic decryption. In a host-based traffic decryption, a host-based agent can decrypt one or more data packets for a connection at a client device. The analyzer module can be configured to determine the client device warrants host-based traffic decryption based on at least one of rarity of endpoint, rarity of timing, rarity of domain, and environment. The host-based agent can the execute a decryption by at least one of receiving a private key from a third-party agent, uploading a public/private key pair into a configuration page from the client network, or retrieving a private key from the client device.

The cyber threat defense platform 100 can then take actions to counter detected potential cyber threats.

An autonomous response module is configured to take an action preapproved by a human user to autonomously attempt to counter a malicious threat. Again, the autonomous response module, rather than a human taking an action, is configured to cause one or more autonomous actions to be taken to contain the cyber threat when a potential cyber threat is detected. i) the cyber security appliance can have the autonomous response module with a user programmable interface. The user programmable interface hosted on the cyber security appliance having any of i) fields, ii) menus, and iii) icons is scripted to allow a user to preauthorize the autonomous response module to take actions to contain the cyber threat. The user programmable fields/menus to allow a user to preauthorize the module to take actions such as killing individual processes, revoking specific privileges, preventing the download of specific files, allowing only processes observed in the pattern of life for peer devices to be active for a set period, asking other endpoint protection platforms (EPPs) to quarantine suspicious files, etc. while not disturbing operations of other processes going on inside that device. The user interface has the granularity in options available to the user to program the autonomous response module to take very specific actions such as killing individual processes, revoking specific privileges while still permitting other permissions for that user, getting live terminal access, preventing the download of specific files, allowing only processes observed in the pattern of life for peer devices to be active for a set period, asking other EPPs to quarantine suspicious files, etc. while not shutting down an entire device, or blocking all outside communications, or revoking one or more but not all of that user's privileges. Actions such as revoking only some user privileges or enforcing the peer pattern of life allow the user to continue working but just not perform certain connections or run certain processes, which most likely a malicious piece of software was initiating, such as accessing and downloading sensitive files while the user, completely unaware of the malicious software using their credentials, is doing a normal activity for that user such as typing out a document or entering data into a program.

Example autonomous actions available to be pre-approved by a human user for the autonomous response module can include a general prompt to the user on the display screen of the end-point computing-device along with the action of: Prevent or slow down activity related to the threat; Quarantine or semi-quarantine people, processes, devices; Feed threat intelligence to EPP and endpoint detection and response (EDR) processes and devices to take third party or vendor specific actions such as quarantine or firewall blocks; ending anomalous processes on the client device, etc.; and in most cases without disrupting the normal day to day activity of users or other processes on the end-point computing-device.

The autonomous response module, rather than a human taking an action, can be configured to cause one or more rapid autonomous actions to be taken to contain the cyber threat when the threat risk parameter from the cyber threat module is equal to or above an actionable threshold. The cyber threat module's configured cooperation with the autonomous response module, to cause one or more autonomous actions to be taken to contain the cyber threat, improves computing devices in the email system by limiting an impact of the cyber threat from consuming unauthorized CPU cycles, memory space, and power consumption in the computing devices via responding to the cyber threat without waiting for some human intervention.

The autonomous response module may tag a specific user to have a lower threshold for an autonomous response, depending on the circumstances of the cyber threat. For example, a chief financial officer can cause much damage to a company by making financial transactions to embezzle funds. If the cyber threat module identifies a cyber threat of a financial nature, the autonomous response module can lower a threshold for the autonomous response upon identifying a tagged user associated with the cyber threat. The autonomous response module can simultaneously employ a number of different clustering methods including matrix-based clustering, density based clustering, and hierarchical clustering techniques to identify which users to tag with which threat type.

The cyber threat defense platform 100 may be hosted on a device, on one or more servers, or in its own cyber threat appliance platform.

FIG. 2 illustrates a block diagram of an embodiment of an example chain of unusual behavior for the network entity in connection with the rest of the network under analysis.

The user interface can display a graph 200 of an example chain of unusual behavior for a SaaS application in connection with the rest of the network under analysis.

The cyber threat module cooperates with one or more machine learning models. The one or more machine learning models are trained and otherwise configured with mathematical algorithms to infer, for the cyber threat analysis, ‘what is possibly happening with the chain of distinct alerts and/or events, which came from the unusual pattern,’ and then assign a threat risk associated with that distinct item of the chain of alerts and/or events forming the unusual pattern.

This is ‘a behavioral pattern analysis’ of what are the unusual behaviors of the network entity, such as a network, a system, a device, a user, or an email, under analysis by the cyber threat module and the machine learning models. The cyber defense system uses unusual behavior deviating from the normal behavior and then builds a chain of unusual behavior and the causal links between the chain of unusual behavior to detect cyber threats. An example behavioral pattern analysis of what are the unusual behaviors may be as follows. The unusual pattern may be determined by filtering out what activities, events, or alerts that fall within the window of what is the normal pattern of life for that network entity under analysis. Then the pattern of the behavior of the activities, events, or alerts that are left, after the filtering, can be analyzed to determine whether that pattern is indicative of a behavior of a malicious actor, such as a human, a program, an email, or other threat. The defense system can go back and pull in some of the filtered out normal activities to help support or refute a possible hypothesis of whether that pattern is indicative of a behavior of a malicious actor. An example behavioral pattern included in the chain is shown in the graph over a time frame of, an example, 7 days. The defense system detects a chain of anomalous behavior of unusual data transfers three times, unusual characteristics in emails in the monitored system three times which seem to have some causal link to the unusual data transfers. Likewise, twice unusual credentials tried unusual behavior of trying to access to sensitive areas or malicious IP addresses and the user associated with the unusual credentials trying unusual behavior has a causal link to at least one of those three emails with unusual characteristics. When the behavioral pattern analysis of any individual behavior or of the chain as a group is believed to be indicative of a malicious threat, then a score of how confident the defense system is in this assessment of identifying whether the unusual pattern was caused by a malicious actor is created. Next, also assigned is a threat level parameter (e.g. score or probability) indicative of what level of threat does this malicious actor pose to the system. Lastly, the cyber threat defense platform is configurable in its user interface of the defense system on what type of automatic response actions, if any, the defense system may take when for different types of cyber threats that are equal to or above a configurable level of threat posed by this malicious actor.

The cyber threat module may chain the individual alerts and events that form the unusual pattern into a distinct item for cyber threat analysis of that chain of distinct alerts or events. The cyber threat module may reference the one or more machine learning models trained on e-mail threats to identify similar characteristics from the individual alerts or events forming the distinct item made up of the chain of alerts or events forming the unusual pattern.

One or more machine learning models may also be trained on characteristics and aspects of all manner of types of cyber threats to analyze the threat risk associated with the chain or cluster of alerts or events forming the unusual pattern. The machine learning technology, using advanced mathematics, can detect previously unidentified threats, without relying on prescribed rules, and automatically defend networks.

The models may perform by the threat detection through a probabilistic change in normal behavior through the application of an unsupervised Bayesian mathematical model to detect behavioral change in computers and computer networks. The core threat detection system is termed the ‘Bayesian probabilistic’. The Bayesian probabilistic approach can determine periodicity in multiple time series data and identify changes across single and multiple time series data for the purpose of anomalous behavior detection. From the email and network raw sources of data, a large number of metrics can be derived each producing time series data for the given metric.

The detectors in the cyber threat module, including the probe module and any SaaS module components, can be discrete mathematical models that implement a specific mathematical method against different sets of variables with the target. Thus, each model is specifically targeted on the pattern of life of alerts and/or events coming from, for example, i) that cyber security analysis tool, ii) analyzing various aspects of the third-party SaaS interactions, iii) coming from specific devices and/or users within a system, etc.

At its core, the cyber threat defense platform mathematically characterizes what constitutes ‘normal’ behavior based on the analysis of a large number/set of different measures of a devices network behavior. The cyber threat defense platform can build a sophisticated ‘pattern of life’—that understands what represents normality for every person, device, email activity, and network activity in the system being protected by the cyber threat defense platform.

As discussed, each machine learning model may be trained on specific aspects of the normal pattern of life for the system such as devices, users, network traffic flow, outputs from one or more cyber security analysis tools analyzing the system, email contact associations for each user, email characteristics, and others. The one or more machine learning models may use at least unsupervised learning algorithms to establish what is the normal pattern of life for the system. The machine learning models can train on both i) the historical normal distribution of alerts and events for that system and ii) a normal distribution information from similar peer systems to establish the normal pattern of life of the behavior of alerts or events for that system. Another set of machine learning models train on characteristics of the SaaS application and the activities and behavior of the SaaS application users to establish a normal for these.

The models can leverage at least two different approaches to detecting anomalies: such as comparing each system's behavior to its own history and comparing that system to its peers' history or such as comparing an email to both characteristics of emails and the activities and behavior of its email users. This multiple source comparison allows the models to avoid learning existing bad behavior as ‘a normal behavior’, because compromised entities, such as devices, users, components, emails will exhibit behavior different to their immediate peers.

In addition, the one or more machine learning models can use the comparison of i) the normal pattern of life for that system corresponding to the historical normal distribution of alerts and events for that system mapped out in the same multiple dimension space to ii) the current chain of individual alerts and events behavior under analysis. This comparison can yield detection of the one or more unusual patterns of behavior within the plotted individual alerts or events, which allows the detection of previously unidentified cyber threats compared to finding cyber threats with merely predefined descriptive objects or signatures. Thus, increasingly intelligent malicious cyber threats, picking and choosing when they take their actions in order to generate low level alerts and event, will still be detected, even though they have not yet been identified by other methods of cyber analysis. These intelligent malicious cyber threats can include malware, spyware, key loggers, malicious links in an email, malicious attachments in an email, and others as well as nefarious internal information technology staff who know intimately how to not set off any high-level alerts or events.

The plotting and comparison are a way to filter out what is normal for that system and then be able to focus the analysis on what is abnormal or unusual for that system. Then for each hypothesis of what could be happening with the chain of unusual events or alerts, the gather module may gather additional metrics from the data store including the pool of metrics originally considered ‘normal behavior’ to support or refute each possible hypothesis of what could be happening with this chain of unusual behavior under analysis.

Note, each of the individual alerts or events in a chain of alerts or events that form the unusual pattern can indicate subtle abnormal behavior. Thus, each alert or event can have a low threat risk associated with that individual alert or event. However, when analyzed as a distinct chain or grouping of alerts or events behavior forming the chain of unusual pattern by the one or more machine learning models, that distinct chain of alerts or events can be determined to now have a much higher threat risk than any of the individual and/or events in the chain.

In addition, modern cyber attacks can be of such severity and speed that a human response cannot happen quickly enough. Thanks to these self-learning advances, a machine may uncover these emerging threats and deploy appropriate, real-time responses to fight back against the most serious cyber threats.

The threat detection system has the ability to self-learn and detect normality in order to spot true anomalies, allowing organizations of all sizes to understand the behavior of users and machines on their networks at both an individual and group level. Monitoring behaviors, rather than using predefined descriptive objects and/or signatures, means that more attacks can be spotted ahead of time and extremely subtle indicators of wrongdoing can be detected. Unlike traditional legacy defenses, a specific attack type or new malware does not have to have been seen first before it can be detected. A behavioral defense approach mathematically models both machine, email, and human activity behaviorally, at and after the point of compromise, in order to predict and catch today's increasingly sophisticated cyber-attack vectors. It is thus possible to computationally establish what is normal, in order to then detect what is abnormal. In addition, the machine learning constantly revisits assumptions about behavior, using probabilistic mathematics. The cyber threat defense platform's unsupervised machine learning methods do not require training data with pre-defined labels. Instead unsupervised machine learning methods may identify key patterns and trends in the data, without the need for human input.

The user interface and output module may also project the individual alerts and/or events forming the chain of behavior onto the user interface with at least three-dimensions of i) a horizontal axis of a window of time, ii) a vertical axis of a scale indicative of the threat risk assigned for each alert and/or event in the chain and a third dimension of iii) a different color for the similar characteristics shared among the individual alerts and events forming the distinct item of the chain. The different color may be red, blue, yellow, or others. For gray scale, the user interface may use different shades of gray, black, and white with potentially different hashing patterns. These similarities of events or alerts in the chain may be, for example, alerts or events are coming from same device, same user credentials, same group, same source identifiers, same destination Internet Protocol addresses, same types of data transfers, same type of unusual activity, same type of alerts, same rare connection being made, same type of events, or others, so that a human can visually see what spatially and content-wise is making up a particular chain rather than merely viewing a textual log of data. Note, once the human mind visually sees the projected pattern and corresponding data, then the human can ultimately decide if a cyber threat is posed. Again, the at least three-dimensional projection helps a human synthesize this information more easily. The visualization onto the user interface allows a human to see data that supports or refutes why the cyber threat defense platform thinks these aggregated alerts or events could be potentially malicious. Also, instead of generating the simple binary outputs ‘malicious’ or ‘benign,’ the cyber threat defense platform's mathematical algorithms produce outputs that indicate differing degrees of potential compromise.

Defense System

FIG. 3 illustrates an example cyber threat defense platform protecting an example network. The example network FIG. 3 illustrates a network of computer systems 50 using a threat detection system. The system depicted by FIG. 3 is a simplified illustration, which is provided for ease of explanation of the invention. The system 50 comprises a first computer system 10 within a building, which uses the threat detection system to detect and thereby attempt to prevent threats to computing devices within its bounds. The first computer system 10 comprises three computers 1, 2, 3, a local server 4, and a multifunctional device (MFD) 5 that provides printing, scanning and facsimile functionalities to each of the computers 1, 2, 3. All of the devices within the first computer system 10 are communicatively coupled via a local area network (LAN) 6. Consequently, all the computers 1, 2, 3 can access the local server 4 via the LAN 6 and use the functionalities of the MFD 5 via the LAN 6.

The LAN 6 of the first computer system 10 is connected to the Internet 20, which in turn provides computers 1, 2, 3 with access to a multitude of other computing devices including server 30 and second computer system 40. Second computer system 40 also includes two computers 41, 42, connected by a second LAN 43.

In this exemplary embodiment of the invention, computer 1 on the first computer system 10 has the threat detection system and therefore runs the threat detection method for detecting threats to the first computer system. As such, it comprises a processor arranged to run the steps of the process described herein, memory required to store information related to the running of the process, as well as a network interface for collecting the required information. This method shall now be described in detail with reference to FIG. 3.

The computer 1 builds and maintains a dynamic, ever-changing model of the ‘normal behavior’ of each user and machine within the system 10. The approach is based on Bayesian mathematics, and monitors all interactions, events and communications within the system 10—which computer is talking to which, files that have been created, networks that are being accessed.

For example, computer 2 is based in a company's San Francisco office and operated by a marketing employee who regularly accesses the marketing network. Computer 2 is active from about 8:30 AM until 6 PM and usually communicates with machines in the company's U.K. office in second computer system 40 between 9.30 AM and midday. The same employee virtually never accesses the employee time sheets, very rarely connects to the company's Atlanta network, and has no dealings in South-East Asia. The threat detection system takes all the information that is available relating to this employee to establish a ‘pattern of life’ for that person, which is dynamically updated as more information is gathered. The ‘normal’ model is used as a moving benchmark, allowing the system to spot behavior on a system that seems to fall outside of this normal pattern of life and to flag this behavior as anomalous, requiring further investigation.

The threat detection system is built to deal with the fact that today's attackers are getting stealthier. An attacker may be ‘hiding’ in a system to ensure that they avoid raising suspicion in an end user, such as by slowing their machine down, using normal software protocol. Any attack process thus stops or ‘backs off’ automatically if the mouse or keyboard is used. However, yet more sophisticated attacks try the opposite, hiding in memory under the guise of a normal process and stealing CPU cycles only when the machine is active, to defeat a relatively-simple policing process. These sophisticated attackers look for activity that is not directly associated with the user's input. As an Advanced Persistent Threat (APT) attack typically has very long mission windows of weeks, months, or years, such processor cycles can be stolen so infrequently that they do not impact machine performance. However cloaked and sophisticated the attack is, the attack will always leave a measurable delta, even if extremely slight, in typical machine behavior, between pre and post compromise. This behavioral delta can be observed and acted on with the form of Bayesian mathematical analysis used by the threat detection system installed on the computer 1.

FIG. 4 illustrates in a block diagram the integration of the threat detection system with other network protections. A network generally has a firewall 402 as a first line of defense. The firewall 402 analyzes packet headers on incoming network data packets to enforce network policy. The firewall 402 may be integrated with an intrusion prevention system (IPS) to analyze the packet header and payload for whole events. Internally, an identity management module 404 controls the access for the users of the network.

A network security module 406 can enforce practices and policies for the network as determined by a network administrator. An encryption module 408 can encrypt communications within the network, as well as encrypting and decrypting communications between network entities and outside entities. An anti-virus or anti-malware module 410 may search packets for known viruses and malware. A patch management module 412 can ensure that security applications within the network have applied the most up-to-date patches. A centralized logging module 414 may track communications both internal to and interactive with the network. The threat detection system can act as real time threat intelligence 416 for the network. The real time threat intelligence may interact with the other defense components to protect the network.

The cyber defense self-learning platform uses machine-learning technology. The machine learning technology, using advanced mathematics, can detect previously unidentified threats, without rules, and automatically defend networks. Note, today's attacks can be of such severity and speed that a human response cannot happen quickly enough. Thanks to these self-learning advances, it is now possible for a machine to uncover emerging threats and deploy appropriate, real-time responses to fight back against the most serious cyber threats.

The cyber threat defense platform builds a sophisticated ‘pattern of life’—that understands what represents normality for every person, device, and network activity in the system being protected by the cyber threat defense platform.

The threat detection system may self-learn and detect normality in order to spot true anomalies, allowing organizations of all sizes to understand the behavior of users and machines on their networks at both an individual and group level. Monitoring behaviors, rather than using predefined descriptive objects and/or signatures, means that more attacks can be spotted ahead of time and extremely subtle indicators of wrongdoing can be detected. Unlike traditional legacy defenses, a specific attack type or new malware does not have to have been seen first before it can be detected. A behavioral defense approach mathematically models both machine and human activity behaviorally, at and after the point of compromise, in order to predict and catch today's increasingly sophisticated cyber-attack vectors. The approach may thus computationally establish what is normal, in order to then detect what is abnormal.

This intelligent system may make value judgments and carry out higher value, more thoughtful tasks. Machine learning requires complex algorithms to be devised and an overarching framework to interpret the results produced. However, when applied correctly these approaches can facilitate machines to make logical, probability-based decisions and undertake thoughtful tasks.

Advanced machine learning is at the forefront of the fight against automated and human-driven cyber-threats, overcoming the limitations of rules and signature-based approaches. For example, the machine learning learns what is normal within a network without depending upon knowledge of previous attacks. The machine learning thrives on the scale, complexity, and diversity of modern businesses, where every device and person is slightly different. The machine learning turns the innovation of attackers against them, so that any unusual activity is visible. The machine learning constantly revisits assumptions about behavior, using probabilistic mathematics. The machine learning is always up to date and not reliant on human input. Utilizing machine learning in cyber security technology is difficult, but when correctly implemented it is extremely powerful. The machine learning means that previously unidentified threats can be detected, even when their manifestations fail to trigger any rule set or signature. Instead, machine learning allows the system to analyze large sets of data and learn a ‘pattern of life’ for what it sees.

FIG. 5 illustrates an application of a cyber threat defense platform using advanced machine learning to detect anomalous behavior. A normal pattern of behavior 510 may describe a set of user or device behavior within a threshold level of occurrence, such as a 98% probability of occurrence based on prior behavior. An anomalous activity 520 may describe a set of user or device behavior that is above the threshold level of occurrence. The cyber threat defense platform can initiate an autonomous response 530 to counteract the anomalous activity, leaving the normal behavior unaffected.

Machine learning can approximate some human capabilities to machines. Machine learning can approximate thought by using past information and insights to form judgments. Machine learning can act in real time so that the system processes information as it goes. Machine learning can self-improve by constantly challenging and adapting the model's machine learning understanding based on new information.

New unsupervised machine learning therefore allows computers to recognize evolving threats, without prior warning or supervision.

Unsupervised Machine Learning

Unsupervised learning works things out without pre-defined labels. This allows the system to handle the unexpected and embrace uncertainty. The system does not always know the characteristics of the target of the search but can independently classify data and detect compelling patterns.

The cyber threat defense platform's unsupervised machine learning methods do not require training data with pre-defined labels. Instead, unsupervised machine learning methods can identify key patterns and trends in the data, without the need for human input. Unsupervised learning provides the advantage of allowing computers to go beyond what their programmers already know and discover previously unknown relationships.

The cyber threat defense platform uses unique implementations of unsupervised machine learning algorithms to analyze network data at scale, intelligently handle the unexpected, and embrace uncertainty. Instead of relying on knowledge of past threats to be able to know what to look for, the cyber threat defense platform may independently classify data and detect compelling patterns that define what may be considered to be normal behavior. Any new behaviors that deviate from this notion of ‘normality’ may indicate threat or compromise. The impact of the cyber threat defense platform's unsupervised machine learning on cyber security is transformative. Threats from within, which would otherwise go undetected, can be spotted, highlighted, contextually prioritized, and isolated using these algorithms. The application of machine learning has the potential to provide total network visibility and far greater detection levels, ensuring that networks have an internal defense mechanism. Machine learning has the capability to learn when to execute automatic responses against the most serious cyber threats, disrupting in progress attacks before they become a crisis for the organization.

This new mathematics not only identifies meaningful relationships within data, but also quantifies the uncertainty associated with such inference. By knowing and understanding this uncertainty, it becomes possible to bring together many results within a consistent framework—the basis of Bayesian probabilistic analysis. The mathematics behind machine learning is extremely complex and difficult to get right. Robust, dependable algorithms are developed, with a scalability that enables their successful application to real-world environments.

Overview

In an embodiment, the cyber threat defense platform's probabilistic approach to cyber security is based on a Bayesian framework. This allows the cyber threat defense platform to integrate a huge number of weak indicators of potentially anomalous network behavior to produce a single clear measure of how likely a network device is to be compromised. This probabilistic mathematical approach provides an ability to understand important information amid the noise of the network, even when the target of a search is unknown.

Ranking threats

Crucially, the cyber threat defense platform's approach accounts for the inevitable ambiguities that exist in data, distinguishing between the subtly differing levels of evidence that different pieces of data may contain. Instead of generating the simple binary outputs ‘malicious’ or ‘benign,’ the cyber threat defense platform's mathematical algorithms produce outputs that indicate differing degrees of potential compromise. This output enables users of the system to rank different alerts in a rigorous manner, prioritizing those that most urgently require action and simultaneously removing the problem of numerous false positives associated with a rule-based approach.

On a core level, the cyber threat defense platform mathematically characterizes what constitutes ‘normal’ behavior based on the analysis of a large number of different measures of network behavior by a device. Such network behavior may include server access, data access, timings of events, credential use, domain name server (DNS) requests, and other similar parameters. Each measure of network behavior is then monitored in real time to detect anomalous behaviors.

Clustering

To be able to properly model what should be considered as normal for a device, the behavior of the device must be analyzed in the context of other similar devices on the network. To accomplish this, the cyber threat defense platform leverages the power of unsupervised learning to algorithmically identify naturally occurring groupings of devices, a task which is impossible to do manually on even modestly sized networks.

In order to achieve as holistic a view of the relationships within the network as possible, the cyber threat defense platform simultaneously employs a number of different clustering methods including matrix-based clustering, density based clustering, and hierarchical clustering techniques. The resulting clusters are then used to inform the modeling of the normative behaviors of individual devices. Clustering analyzes behavior in the context of other similar devices on the network. Clustering algorithms identify naturally occurring groupings of devices, which is impossible to do manually. Further, the cyber threat defense platform may simultaneously run multiple different clustering methods to inform the models.

Network topology

Any cyber threat detection system must also recognize that a network is far more than the sum of its individual parts, with much of its meaning contained in the relationships among its different entities. Plus, any cyber threat defense platform must further recognize that complex threats can often induce subtle changes in this network structure. To capture such threats, the cyber threat defense platform employs several different mathematical methods in order to be able to model multiple facets of a network topology.

One approach is based on iterative matrix methods that reveal important connectivity structures within the network. In tandem with these, the cyber threat defense platform has developed innovative applications of models from the field of statistical physics, which allow the modeling of a network's ‘energy landscape’ to reveal anomalous substructures that may be concealed within.

Network structure

A further important challenge in modeling the behaviors of network devices, as well as of networks themselves, is the high-dimensional structure of the problem with the existence of a huge number of potential predictor variables. Observing packet traffic and host activity within an enterprise local area network (LAN), wide area network (WAN) and Cloud is difficult because both input and output can contain many inter-related features, such as protocols, source and destination machines, log changes, rule triggers, and others. Learning a sparse and consistent structured predictive function is crucial to avoid over fitting.

In this context, the cyber threat defense platform has employed a cutting edge large-scale computational approach to learn sparse structure in models of network behavior and connectivity based on applying L1-regularization techniques, such as a Least Absolute Shrinkage and Selection Operator (LASSO) method. This allows for the discovery of true associations between different network components and events that can be cast as efficiently solvable convex optimization problems and yield parsimonious models.

Recursive Bayesian Estimation

To combine these multiple analyses of different measures of network behavior to generate a single comprehensive picture of the state of each device, the cyber threat defense platform takes advantage of the power of Recursive Bayesian Estimation (RBE) via an implementation of the Bayes filter.

Using RBE, the cyber threat defense platform's mathematical models can constantly adapt themselves, in a computationally efficient manner, as new information becomes available to the system. They continually recalculate threat levels in the light of new evidence, identifying changing attack behaviors where conventional signature-based methods fail.

The cyber threat defense platform's innovative approach to cyber security has pioneered the use of Bayesian methods for tracking changing device behaviors and computer network structures. The core of the cyber threat defense platform's mathematical modeling is the determination of normative behavior, enabled by a sophisticated software platform that allows for its mathematical models to be applied to new network data in real time. The result is a system that can identify subtle variations in machine events within a computer networks behavioral history that may indicate cyber-threat or compromise.

The cyber threat defense platform uses mathematical analysis and machine learning to detect potential threats, allowing the system to stay ahead of evolving risks. The cyber threat defense platform approach means that detection no longer depends on an archive of previous attacks. Instead, attacks can be spotted against the background understanding of what represents normality within a network. No pre-definitions are needed, which allows for the best possible insight and defense against today's threats. On top of the detection capability, the cyber threat defense platform can create digital antibodies automatically, as an immediate response to the most threatening cyber breaches. The cyber threat defense platform approach both detects and defends against cyber threat. Genuine unsupervised machine learning eliminates the dependence on signature-based approaches to cyber security, which are not working. The cyber threat defense platform's technology can become a vital tool for security teams attempting to understand the scale of their network, observe levels of activity, and detect areas of potential weakness. These no longer need to be manually sought out, but rather are flagged by the automated system and ranked in terms of their significance.

Machine learning technology is the fundamental ally in the defense of systems from the hackers and insider threats of today, and in formulating response to unknown methods of cyber-attack. It is a momentous step change in cyber security. Defense must start within.

An Example Method

The threat detection system shall now be described in further detail with reference to a flow of the process carried out by the threat detection system for automatic detection of cyber threats through probabilistic change in normal behavior through the application of an unsupervised Bayesian mathematical model to detect behavioral change in computers and computer networks.

The core threat detection system is termed the ‘Bayesian probabilistic’. The Bayesian probabilistic is a Bayesian system of automatically determining periodicity in multiple time series data and identifying changes across single and multiple time series data for the purpose of anomalous behavior detection.

FIG. 6 illustrates a flowchart of an embodiment of a method for modeling human, machine or other activity. The cyber threat defense platform initially ingests data from multiple sources (Block 602). The raw data sources include, but are not limited to raw network Internet Protocol (IP) traffic captured from an IP or other network Test Access Points (TAP) or Switched Port Analyzer (SPAN) port; machine generated log files; building access (“swipe card”) systems; IP or non-IP data flowing over an Industrial Control System (ICS) distributed network; individual machine, peripheral or component power usage; telecommunication signal strength; or machine level performance data taken from on-host sources, such as central processing unit (CPU) usage, memory usage, disk usage, disk free space, network usage, and others.

The cyber threat defense platform derives second order metrics from that raw data (Block 604). From these raw sources of data, multiple metrics can be derived, each producing time series data for the given metric. The data are bucketed into individual time slices. For example, the number observed could be counted per 1 second, per 10 seconds or per 60 seconds. These buckets can be combined at a later stage where required to provide longer range values for any multiple of the chosen internal size. For example, if the underlying time slice chosen is 60 seconds long, and thus each metric time series stores a single value for the metric every 60 seconds, then any new time series data of a fixed multiple of 60 seconds (such as 120 seconds, 180 seconds, 600 seconds etc.) can be computed with no loss of accuracy. Metrics are chosen directly and fed to the Bayesian probabilistic by a lower order model which reflects some unique underlying part of the data, and which can be derived from the raw data with particular domain knowledge. The metrics that are obtained depends on the threats that the system is looking for. In order to provide a secure system, the cyber threat defense platform commonly obtains multiple metrics relating to a wide range of potential threats. Communications from components in the network contacting known suspect domains.

The actual specific metrics used are largely irrelevant to the Bayesian probabilistic system, as long as a metric is selected. Metrics derived from network traffic could include data such as the number of bytes of data entering or leaving a networked device per time interval, file access, the commonality or rarity of a communications process, an invalid secure-sockets layer (SSL) certification, a failed authorization attempt, or email access patterns.

In the case where transmission control protocol (TCP), user datagram protocol (UDP), or other Transport Layer IP protocols are used over the IP network, and in cases where alternative Internet Layer protocols are used, such as Internet Control Message Protocol (ICMP) or Internet Group Message Protocol (IGMP), knowledge of the structure of the protocol in use and basic packet header analysis can be utilized to generate further metrics. Such further metrics may include the number of multicasts per time interval originating from a networked device and intended to reach publicly addressable IP ranges, the number of internal link-local IP Broadcast requests originating from a networked device, the size of the packet payload data, or the number of individual TCP connections made by a device, or data transferred by a device, either as a combined total across all destinations or to any definable target network range, such as a single target machine or a specific network range.

In the case of IP traffic where the Application Layer protocol can be determined and analyzed, further types of time series metric can be defined. These time series metrics may include, for example, the number of DNS requests a networked device generates per time interval, again either to any definable target network range or in total; the number of Simple Mail Transfer Protocol (SMTP), Post Office Protocol (POP) or Internet Message Access Protocol (IMAP) logins or login failures a machine generates per time interval; the number of Lightweight Directory Access Protocol (LDAP) logins or login failures generated; data transferred via file sharing protocols such as Server Message Block (SMB), SMB2, File Transfer Protocol (FTP), or others; or logins to Microsoft Windows Active Directory, Secure Shell (SSH) or Local Logins to Linux or Unix-like systems, or other authenticated systems such as Kerberos.

The raw data required to obtain these metrics may be collected via a passive fiber or copper connection to the networks internal switch gear, from virtual switching implementations, cloud-based systems, or communicating devices themselves. Ideally, the system receives a copy of every communications packet to provide full coverage of an organization.

For other sources, a number of domain specific time series data are derived, each chosen to reflect a distinct and identifiable facet of the underlying source of the data, which in some way reflects the usage or behavior of that system over time.

Many of these time series data sets are extremely sparse, with most data points equal to 0. Examples would be employee's using swipe cards to access a building or part of a building, or user's logging into their workstation, authenticated by Microsoft Windows Active Directory Server, which is typically performed a small number of times per day. Other time series data sets are much more populated, such as, the size of data moving to or from an always-on Web Server, the Web Servers CPU utilization, or the power usage of a photocopier.

Regardless of the type of data, such time series data sets, whether originally produced as the result of explicit human behavior or an automated computer or other system to exhibit periodicity, have the tendency for various patterns within the data to recur at approximately regular intervals. Furthermore, such data may have many distinct but independent regular time periods apparent within the time series.

Detectors carry out analysis of the second order metrics (Block 606). Detectors are discrete mathematical models that implement a specific mathematical method against different sets of variables with the target network. For example, Hidden Markov Models (HMM) may look specifically at the size and transmission time of packets between nodes. The detectors are provided in a hierarchy that is a loosely arranged pyramid of models. Each detector model effectively acts as a filter and passes its output to another model higher up the pyramid. At the top of the pyramid is the Bayesian probabilistic that is the ultimate threat decision making model. Lower order detectors each monitor different global attributes or ‘features’ of the underlying network and or computers. These attributes may be value over time for all internal computational features such as packet velocity and morphology, endpoint file system values, and TCP/IP protocol timing and events. Each detector is specialized to record and make decisions on different environmental factors based on the detectors own internal mathematical model such as an HMM.

While the threat detection system may be arranged to look for any possible threat, in practice the system may keep watch for one or more specific threats depending on the network in which the threat detection system is being used. For example, the threat detection system provides a way for known features of the network such as desired compliance and Human Resource policies to be encapsulated in explicitly defined heuristics or detectors that can trigger when in concert with set or moving thresholds of probability abnormality coming from the probability determination output. The heuristics are constructed using complex chains of weighted logical expressions manifested as regular expressions with atomic objects that are derived at run time from the output of data measuring/tokenizing detectors and local contextual information. These chains of logical expression are then stored in online libraries and parsed in real-time against output from the measures/tokenizing detectors. An example policy could take the form of “alert me if any employee subject to HR disciplinary circumstances (contextual information) is accessing sensitive information (heuristic definition) in a manner that is anomalous when compared to previous behavior (Bayesian probabilistic output)”. In other words, different arrays of pyramids of detectors are provided for detecting particular types of threats.

The analysis performed by the detectors on the second order metrics then outputs data in a form suitable for use with the model of normal behavior. As will be seen, the data is in a form suitable for comparing with the model of normal behavior and for updating the model of normal behavior.

The threat detection system computes a threat risk parameter indicative of a likelihood of there being a threat using automated adaptive periodicity detection mapped onto observed behavioral pattern-of-life analysis (Block 608). This deduces that a threat over time exists from a collected set of attributes that themselves have shown deviation from normative collective or individual behavior. The automated adaptive periodicity detection uses the period of time the Bayesian probabilistic has computed to be most relevant within the observed network or machines. Furthermore, the pattern of life analysis identifies how a human or machine behaves over time, such as when they typically start and stop work. Since these models are continually adapting themselves automatically, they are inherently harder to defeat than known systems. The threat risk parameter is a probability of there being a threat in certain arrangements. Alternatively, the threat risk parameter is a value representative of there being a threat, which is compared against one or more thresholds indicative of the likelihood of a threat.

In practice, the step of computing the threat involves comparing current data collected in relation to the user with the model of normal behavior of the user and system being analyzed. The current data collected relates to a period in time, this could be in relation to a certain influx of new data or a specified period of time from a number of seconds to a number of days. In some arrangements, the system is arranged to predict the expected behavior of the system. The expected behavior is then compared with actual behavior in order to determine whether there is a threat.

The system uses machine learning or Artificial Intelligence to understand what is normal inside a company's network, and when something's not normal. The system then invokes automatic responses to disrupt the cyber-attack until the human team can catch up. This could include interrupting connections, preventing the sending of malicious emails, preventing file access, preventing communications outside of the organization, etc. The approach begins in as surgical and directed way as possible to interrupt the attack without affecting the normal behavior of, for example, a laptop. If the attack escalates, the cyber threat defense platform may ultimately quarantine a device to prevent wider harm to an organization.

In order to improve the accuracy of the system, a check can be carried out in order to compare current behavior of a user with associated users, such as users within a single office. For example, if there is an unexpectedly low level of activity from a user, this may not be due to unusual activity from the user, but rather a factor affecting the office as a whole. Various other factors can be considered in order to assess whether abnormal behavior is actually indicative of a threat.

Finally, the cyber threat defense platform determines, based on the threat risk parameter, as to whether further action need be taken regarding the threat (Block 610). A human operator may make this determination after being presented with a probability of there being a threat. Alternately, an algorithm may make the determination, such as by comparing the determined probability with a threshold.

In one arrangement, given the unique global input of the Bayesian probabilistic, a form of threat visualization is provided in which the user can view the threat landscape across all internal traffic and do so without needing to know how their internal network is structured or populated and in such a way as a ‘universal’ representation is presented in a single pane no matter how large the network. A topology of the network under scrutiny is projected automatically as a graph based on device communication relationships via an interactive 3D user interface. The projection can scale linearly to any node scale without prior seeding or skeletal definition.

The threat detection system that has been discussed above therefore implements a propriety form of recursive Bayesian estimation to maintain a distribution over the probability state variable. This distribution is built from the complex set of low-level host, network, and traffic observations or ‘features’. These features are recorded iteratively and processed in real time on the platform. A plausible representation of the relational information among entities in dynamic systems in general, such as an enterprise network, a living cell or a social community, or indeed the entire internet, is a stochastic network, which is topological rewiring and semantically evolving over time. In many high-dimensional structured input/output problems, such as the observation of packet traffic and host activity within a distributed digital enterprise, where both input and output can contain tens of thousands to millions of interrelated features (data transport, host-web-client dialogue, log change and rule trigger, etc.), learning a sparse and consistent structured predictive function is challenged by a lack of normal distribution. To overcome this, the threat detection system comprise a data structure that decides on a rolling continuum rather than a stepwise method in which recurring time cycles, such as the working day, shift patterns, and other routines are dynamically assigned, thus providing a non-frequentist architecture for inferring and testing causal links between explanatory variables, observations and feature sets. This permits an efficiently solvable convex optimization problem and yield parsimonious models. In such an arrangement, the threat detection processing may be triggered by the input of new data. Alternatively, the threat detection processing may be triggered by the absence of expected data. In some arrangements, the processing may be triggered by the presence of a particular actionable event.

The method and system are arranged to be performed by one or more processing components with any portions of software stored in an executable format on a computer readable medium. The computer readable medium may be non-transitory and does not include radio or other carrier waves. The computer readable medium could be, for example, a physical computer readable medium such as semiconductor or solid state memory, magnetic tape, a removable computer diskette, a random access memory (RAM), a read-only memory (ROM), a rigid magnetic disc, and an optical disk, such as a CD-ROM, CD-RAN or DVD.

The various methods described above may be implemented by a computer program product. The computer program product may include computer code arranged to instruct a computer to perform the functions of one or more of the various methods described above. The computer program and/or the code for performing such methods may be provided to an apparatus, such as a computer, on a computer readable medium or computer program product. For the computer program product, a transitory computer readable medium may include radio or other carrier waves.

An apparatus such as a computer may be configured in accordance with such code to perform one or more processes in accordance with the various methods discussed herein.

FIG. 7 illustrates a flowchart of an embodiment of a method for identifying an anomalous event from network event data. The cyber threat defense platform can use a probe module configured to collect probe data from one or more probes deployed to one or more client devices (Block 702). The network entity represents at least one of a user and a network device. The probe data can describe network-administrated activity SaaS activity by the network entity.

The cyber threat defense platform can use an email module configured to collect email data from the email service (Block 704). The cyber threat defense platform uses a coordinator module to contextualize the email data from the email module with the probe data from the probe module to create a combined data set for analysis (Block 706). The cyber threat defense platform uses a cyber threat module configured to analyze the combined data set using at least one machine-learning model to spot behavior on the network deviating from the normal benign behavior (Block 708). The at least one machine-learning model trains on a normal benign behavior of a network entity. The at least one machine-learning model uses a normal behavior benchmark as a benchmark of at least one parameter corresponding to a normal pattern of activity for the network to spot deviant behavior.

The cyber threat defense platform has a comparison module that compares the combined data set, including the third-party event data, to the at least one machine-learning model to spot behavior on the network deviating from a normal benign behavior of that network entity (Block 710). The comparison module can identify whether the network entity is in a breach state of the normal behavior benchmark (Block 712). The cyber threat module can identify whether the breach state and a chain of relevant behavioral parameters deviating from the normal benign behavior of that network entity correspond to a cyber threat (Block 714).

The cyber threat defense platform can use a user interface module configured to present a graphical representation of the cyber threat in a graphical user interface (Block 716). The cyber threat defense platform can use an autonomous response module configured to select an autonomous response to take in response to the cyber threat (Block 718). The autonomous response can be, for example, reducing permissions of the network entity or disabling a user account of the network entity. The autonomous response module can send an alert of the cyber threat with a suggested response to the cyber threat to an internal system administrator or the third-party operator (Block 720). The autonomous response module can execute the autonomous response in response to the cyber threat (Block 722).

FIG. 8 illustrates third-party event data. The network event data may represent a variety of administrative events. The administrative event can be a login event 802 describing the user logging in to a user account for an online application or service. The administrative event can be a failed login event 804 describing the failure of a user to log in to a user account for the online application or service. The administrative event can be a resource creation event 806 describing the creation of a virtual instance of the online application. The administrative event can be a resource view event 808 describing a viewing of a virtual instance of the online application. The administrative event can be a resource modification event 810 describing the modification of a virtual instance of the online application. The administrative event can be a resource deletion event 812 describing the deletion of a virtual instance of the online application. The administrative event can be a file upload event 814 describing the uploading of a file to the online application. The administrative event can be a file download event 816 describing the downloading of a file from the online application. The administrative event can be an administrative action event 818 describing an action at the administrative level to the online application.

The cyber threat defense platform can use a variety of methods to retrieve administrative events. The network module can pull the administrative events from the client device on an event-by-event basis. FIG. 9 illustrates a flowchart of an embodiment of a method for pulling data from a client device. The network module is configured to direct one or more connectors to send a Hypertext Transfer Protocol Secure (HTTPS) event request to the client network (Block 902). The HTTPS event request asks for an administrative event from an audit log of the client network. The one or more connectors generates the HTTPS event request (Block 904). The one or more connectors sends the HTTPS event request to the client network to request the administrative event (Block 906). The network module is configured to receive an administrative event from the one or more connectors in response to the event request (Block 908). The network module is configured to harvest metadata of the administrative event (Block 910).

The autonomous response module can use threat risk parameter generated by the cyber threat module to autonomously determine a response. FIG. 10 illustrates a flowchart of an embodiment of a method for identifying an autonomous response. The cyber threat defense platform can have the cyber threat module configured to generate a threat risk parameter listing a set of values describing aspects of the cyber threat (Block 1002). The cyber threat defense platform can have the autonomous response module configured to generate a benchmark matrix having a set of benchmark scores (Block 1004). The autonomous response module can identify a tagged user associated with the cyber threat (Block 1006). The autonomous response module can lower a threshold for the autonomous response upon identifying a tagged user associated with the cyber threat (Block 1008). The autonomous response module can compare the threat risk parameter to the benchmark matrix to determine the autonomous response (Block 1010). The autonomous response module can determine an autonomous response based on the comparison (Block 1012).

The cyber threat defense platform can generate a threat risk parameter to describe the relative dangers of an anomalous event. FIG. 11 illustrates a block diagram of a threat risk parameter. The threat risk parameter can have a threat type 1102 describing the type of threat identified, such as financial, administrative, information technology, production, or other. The threat risk parameter can have a confidence score 1104 indicating a breach likelihood describing a probability that the template entity is in the breach state. The threat risk parameter can have a severity score 1106 indicating a percentage that the template entity in the breach state is deviating from normal behavior, as represented by the at least one model. The threat risk parameter can have a consequence score 1108 indicating a severity of damage attributable to the breach state.

FIG. 12 illustrates a flowchart of an embodiment of a method for generating a threat risk parameter. The cyber threat module can generate a threat risk parameter listing a set of values describing aspects of the breach state (Block 1202). The cyber threat module can identify a threat type for the cyber threat by using a variety of clustering techniques to group the threat with other identified cyber threats (Block 1604). The cyber threat module can generate a confidence score (Block 1206). The cyber threat module can generate a severity score (Block 1208). The cyber threat module can generate a consequence score (Block 1210). The cyber threat module can populate the threat risk parameter with at least one of the confidence score, the severity score, and the consequence score (Block 1212).

FIG. 13 illustrates a block diagram of a benchmark matrix. The autonomous response module, in conjunction with the cyber threat module, can populate the benchmark matrix with moving benchmarks that can adapt to the changing nature of both the network and threats to the network. The benchmark matrix can have a confidence benchmark 1302 indicating a breach likelihood describing a probability above which the template entity is in the breach state. The benchmark matrix can have a severity benchmark 1304 indicating a percentage above which the template entity is in the breach state. The benchmark matrix can have a consequence benchmark 1306 indicating a severity of damage attributable to the breach state that above which immediate action is to be taken. The autonomous response module can adjust these benchmarks as more data is added and greater user input is received.

The autonomous response module can assign a weight to each bench mark score to assign a relative importance to each bench mark score to factor in a decision to send an inoculation notice. As with the benchmarks, these weights may evolve over time. For example, the benchmark matrix can have a confidence weight 1308 indicating the importance of the confidence benchmark, a severity weight 1310 indicating the importance of the severity benchmark, and a consequence weight 1312 indicating the importance of the consequence benchmark. Using these assigned weights, different deviations from the benchmarks may have a greater result on the final decision to send and inoculation notice.

FIG. 14 illustrates a flowchart of an embodiment of a method for comparing analyzed input data to a benchmark to trigger an inoculation notice. The autonomous response module can generate a benchmark matrix having a set of benchmark scores to determine an autonomous response (Block 1402). The autonomous response module can populate the benchmark scores in the benchmark matrix based on data gathered during the breach identification process (Block 1404). The autonomous response module can assign a weight to each benchmark score to assign a relative importance to each benchmark score (Block 1406).

Interest Classifiers

The cyber threat detection platform is configured to perform a packet inspection by analyzing a subset of each possible connection. One approach of monitoring connections is to process and inspect all connection traffic to a client device. This approach may not be computationally smart, as not every connection is ‘interesting’ or entirely able to be parsed. An alternative approach is to perform connection-specific deep packet inspection and processing. In this approach, a traffic manager module, such as in a host-based agent, a virtualized sensor, a centralized physical appliance, or a centralized cloud appliance, can process connections differently based upon how interesting they are, how much information a cyber threat detection platform can parse from the protocol, and whether a security team would wish to see the connection. This approach would branch off or filter uninteresting connections to save computation, automatically decrypt or generate packet captures (PCAPs) for interesting connections, and only parse metadata for connections which do not present much value. The traffic manager module can ‘shunt’ connections. In other words, the network card can stop processing the actual content of a connection and only supply the metadata, such as packet numbers or bytes, to hugely decrease computational time.

The connection-specific approach can cooperate with a network card that not only processes traffic, but is aware of the flows passing through it, such as volumes, connection types, or protocols. The connection-specific approach can shunt connections based on just the metadata being useful, such as with some encrypted protocols, or on the connection being a large connection deemed uninteresting. The connection-specific deep packet inspection and processing approach can also ‘unshunt’ if a connection becomes interesting. For example, the cyber threat defense platform can instruct the network card to start processing the data again because the data connection has been deemed interesting. The cyber threat defense platform can identify an interesting connection based on the connection being anomalous in the context of the device's historic behavior or device peer group behavior, multiple connections with similar characteristics across several devices raising the overall anomaly, or later actions changing the “interestingness” status of an initially uninteresting connection. An autonomous action module can then end the connection or check that the connection has been successfully blocked by retrieving data about the connection to spoof reset (RST) packets or supply that information to a third-party firewall. An interesting connection may also be one that becomes anomalous enough that a security system, decryption methodology, or team may want to decrypt the data at the packet level in a packet capture. Decryption, being computationally expensive and slow, is reserved for connections with the most investigative value. The deep packet inspection engine can then collect the packet level data so the security team can do so.

FIG. 15 illustrates a block diagram of a physical traffic manager module. A centralized physical appliance can have a traffic manager module using a network card. The network card can register a connection from a network to transmit a series of one or more data packets. The network card can analyze the one or more data packets to identify potential cyberthreats. After analysis by the network card, the network card can pass the data packets to a processor for decryption and processing. The processor can transmit any data to the network by passing data to an offload module. The offload module can packetize the data and send the new data packets to the network.

The network card can have a registration module to register a connection between one or more devices within a client network to transmit a series of one or more data packets. The network card can have a classifier module configured to execute a comparison of features of the connection to a set of interest criteria to determine an interest level for the cyber threat defense platform in the connection. The classifier module can adjust the set of interest criteria based on the set of host parameters for client network. The set of host parameters can be at least one of storage capacity, processing capacity, and network bandwidth. The classifier module can be configured to apply an interest classifier describing the interest level to the connection based on the comparison. The network card can have a deep packet inspection (DPI) module to examine the one or more data packets of the connection for cyber threats if the interest classifier indicates interest. The network card can have a diverter configured to shunt the one or more data packets of the connection away from the deep packet inspection engine if the interest classifier indicates no interest.

FIG. 16 illustrates a block diagram of a virtual traffic manager module. A host-based agent, hypervisor, or centralized cloud appliance can have a traffic manager module using a virtual netmap module. The netmap module can register a connection from a network to transmit a series of one or more data packets. The netmap module can analyze the one or more data packets to identify potential cyberthreats. After analysis by the netmap module, the netmap module can pass the data packets to a processor for decryption and processing. The processor can transmit any data to the network by passing data to an offload module. The offload module can packetize the data and send the new data packets to the network.

The virtual netmap module can have a registration module to register a connection between one or more devices within a client network to transmit a series of one or more data packets. The virtual netmap module can have a classifier module configured to execute a comparison of features of the connection to a set of interest criteria to determine an interest level for the cyber threat defense platform in the connection. The classifier module can adjust the set of interest criteria based on the set of host parameters for client network. The set of host parameters can be at least one of storage capacity, processing capacity, and network bandwidth. The classifier can be configured to apply an interest classifier describing the interest level to the connection based on the comparison. The virtual netmap module can have a deep packet inspection (DPI) module to examine the one or more data packets of the connection for cyber threats if the interest classifier indicates interest. The virtual netmap module can have a diverter configured to shunt the one or more data packets of the connection away from the deep packet inspection engine if the interest classifier indicates no interest.

FIG. 17 illustrates a flowchart of an embodiment of a method for establishing interesting criteria. The traffic manager module can receive a set of interest criteria from the analyzer module of the cyber threat defense platform (Block 1702). The classifier module of the traffic manager module can determine a set of host parameters for the client device (Block 1704). The classifier module can adjust the set of interest criteria based on the set of host parameters (Block 1706). The classifier module can store the set of interest criteria for future use (Block 1708).

FIG. 18 illustrates a flowchart of an embodiment of a method for processing a data connection with a deep packet inspection engine. A registration module of a traffic manager module can register a connection between one or more devices within a client network to transfer a series of one or more data packets (Block 1802). A classifier module of the traffic manager module can execute a comparison of features of the connection to a set of interest criteria to determine an interest level for the cyber threat defense platform in the connection (Block 1804). The classifier module can determine that the connection is interesting based on the connection being at least one of a short-lived connection, able to be decrypted within a parameter set for the client device, or outside a normal connection pattern (Block 1806). The classifier module can apply an interest classifier describing the interest level as interesting to the connection based on the comparison (Block 1808). A diverter of the traffic manager module can pass the one or more data packets of the connection to a deep packet inspection engine for further examination for cyber threats if the interest classifier indicates interest (Block 1810). The deep packet inspection engine can collect a set of packet metadata for the one or more data packets of a passthrough connection (Block 1812). An offload module of the traffic manager module can send the set of packet metadata to an analyzer module of a centralized cyber threat defense platform when processing performed external to the centralized cyber threat defense platform (Block 1814).

FIG. 19 illustrates a flowchart of an embodiment of a method for shunting a data connection past a deep packet inspection engine. A registration module of a traffic manager module can register a connection between one or more devices within a client network to transfer a series of one or more data packets (Block 1902). A classifier module of the traffic manager module can execute a comparison of features of the connection to a set of interest criteria to determine an interest level for the cyber threat defense platform in the connection (Block 1904). The classifier module can determine that the connection is not interesting based on the connection being at least one of a long-lived connection, unable to be decrypted within a parameter set for the client device, and within a normal connection pattern (Block 1906). The classifier module can apply an interest classifier describing the interest level as not interesting to the connection based on the comparison (Block 1908). A diverter of the traffic manager module can shunt the one or more data packets of the connection away from the deep packet inspection engine if the interest classifier indicates no interest (Block 1910). A processing module of the client device can collect a set of packet metadata for the one or more data packets of the shunted connection (Block 1912). An offload module of the traffic manager module can send the set of packet metadata to an analyzer module of a centralized cyber threat defense platform when processing performed external to the centralized cyber threat defense platform (Block 1914). The classifier module can monitor at least one of a connection length and a payload size for a shunted connection (Block 1916).

FIG. 20 illustrates a flowchart of an embodiment of a method for processing a data connection with a dropped data packet. The traffic manager module can receive a passthrough connection in the deep packet inspection engine (Block 2002). The deep packet inspection engine can identify a dropped packet in the passthrough connection (Block 2004). The classifier module can apply an updated interest classifier describing a different interest level based on the dropped packet (Block 2006). The diverter can shunt the passthrough connection with the dropped packet away from the deep packet inspection engine (Block 2008).

FIG. 21 illustrates a flowchart of an embodiment of a method for handling data connections during an anomalous event. A cyber threat module of the cyber threat defense platform can detect an anomalous event at the client device (Block 2102). A diverter of the traffic manager module can reconnect a shunted connection to the deep packet inspection engine upon detection of an anomalous event at the client device (Block 2104). An autonomous action module can retrieve data about the connection to spoof reset (RST) packets to end the connection or check that the connection has been successfully blocked (Block 2104). The autonomous action module can sever the connection upon detection by the analyzer module of an anomalous event at the client device (Block 2108). A classifier module of the traffic manager module can adjust the set of interest criteria based on the anomalous event (Block 2110).

Host-Based Decryption

The cyber threat detection platform is configured to data mine communication protocols using decryption to protect the network from cyber threats in this network using an encrypted communication protocol. The encryption of domain name system (DNS) traffic and other protocols has increased in popularity as the security risks of plaintext protocols become evident. A host-based traffic decryption approaches decryption in a deep packet inspection (DPI) engine in three ways. One, the host-based agent can receive private keys from a third-party proxy or agent. Two, the host-based agent can upload public/private key pairs into the centralized appliance associated with the host-based agents via a secure shell console or other interface. Three, the host-based agent can retrieve the key from a client device. A third-party proxy or agent works with a device-host based cyber threat detection and response platform, which uses a universal translator to instruct third party systems and retrieve data from them. Host-based key retrieval is made up of two possible approaches, process memory retrieval or a personal firewall proxy.

In the process memory retrieval approach, a module of the host-based agent observes when a new connection is opened on port 443 and informs another module of the process that opened the connection. This process memory retrieval approach is not limited to this port, but rather secure transfers are done using port 443, the standard port for HTTPS traffic. The other module will locate the memory for the process that opened the connection and scan the memory for patterns which may be encryption keys. The other module will then pass this key to the cyber threat detection platform via a secure system that will route the key and process information to the correct appliance and correct module, such as the DPI engine, where the private key can be matched to observed traffic and decrypted. The personal firewall proxy mode is where the host-based agent acts a personal firewall, with the traffic controlled on a device-by-device basis. The host-based agent acts as a “Man in the Middle” to the traffic to see the traffic in a decrypted format or retrieve the keys before the keys leaves the device. The personal firewall proxy mode can use an endpoint agent which is performing process analysis and acting as a man-in the-middle proxy.

FIG. 22 illustrates a flowchart of an embodiment of a method for using host-based decryption for data connections on client devices. An analyzer module of the cyber threat defense platform can determine the client device warrants host-based traffic decryption (Block 2202). The analyzer module can consider rarity of endpoint, rarity of timing, rarity of domain, or environment in making this determination. The analyzer module can flag the client device for host-based traffic decryption (Block 2204). The deep packet inspection engine can execute the decryption at the host-based agent (Block 2206). The deep packet inspection engine can receive a private key from a third-party agent. Alternately, the deep packet inspection engine on a host-based agent can forward encrypted traffic to the centralized cyber security defense platform where a public/private key pair has been supplied, allowing the deep packet inspection engine located on that cyber security defense platform to instead perform the decryption and processing. Otherwise, the deep packet inspection engine can retrieve a private key from the client network.

External Storage for Interesting Packet Data

The cyber security defense platform can cooperate with a storage device, such as a database on the Internet or on a private database in the cloud, to store interesting packet data for longer and more in-depth analysis such that the amount of storage is minimized as a concern. The cyber security defense platform can save a great amount of packets in the storage compared to storage merely on the cyber security platform itself. Further, the storage can store the packets for longer duration because the storage is not limited in storage size. Additionally, the storage can run more computational artificial intelligence on the data because of the external storage. The cyber security defense platform can write packet data which has been processed by the deep packet Inspection (DPI) engine to limited-time storage for retrieval by operators who wish to perform detailed investigations. Due to the sheer volume of data traversing the monitored network and undergoing deep packet inspection, only a limited amount of data tends to be stored. Packet data is therefore retained on the basis of level of interest. Data may be configured for stepped expiry based upon level of interest, where interesting data is stored in long term storage and connections with lower level of “interestingness” are expired earlier. The level of interest may be derived from the anomalousness of the protocol, the anomalousness of a factor of the connection (such as the source, the destination, the timing), or any number of additional metrics. A user can specify packets with x type of metrics be sent to external storage through the user interface. The classifier module can use a classifier for default identification of interesting data packets to augment a user's input.

Performance of artificial intelligence-powered inspection of individual byte-level data is too computationally expensive and slow when packet data is held within a centralized cybersecurity platform, or on a virtualized probe, requiring performances by processes resident on the platform or probe. When stored externally in a secure extended storage, an external infrastructure may be utilized to perform artificial intelligence analysis on packet data without sharing computational processing power with the probe or cybersecurity platform. The external infrastructure may be a locally located virtual machine or a machine learning microservice, such as Amazon AWS Machine Learning. Analysis may include inspection of byte-level strings for anomaly using Transformers or other deep learning models.

A secure extension of the storage capacity, and some data types maintained within the cyber security appliance, in most cases, can directly cooperate and communicate with the cyber security defense platform. The cyber security defense platform has a user interface on a display to interface with the end user. The cyber security defense platform, whether physical or virtualized, securely connects to and communicates with a separate external storage. For example, the external storage a cloud-based Simple Storage System (S3) bucket within the same virtual private cloud (VPC) or within a virtual private cloud managed by the organization supplying the cyber security defense platform. The virtualized probes performing the deep packet inspection write interesting connections directly to this external to the probe storage to be accessed by the connected cyber security defense platform via an application programming interface call, a tunnel with multiple factor verification, a connection via the connected probe, or an additional communication method. This virtualization can allow the probes to auto scale as traffic volume increases or decreases without the destruction of data.

Additional benefits of this approach are larger and longer-term storage. Additional storage clusters or blobs can be created to deal with demand. The option for standard cyber security defense platform deployments can utilize external packet storage in a managed VPC as an additional service. The packet data may also be queried or searchable via an application programming interface from a compatible service, such as an intelligence tool in the customer network. Finally, this smaller subset of data allows for potential machine learning approaches which would not be feasible on larger datasets due to computational expense.

FIG. 23 illustrates a flowchart of an embodiment of a method for offsite storage of packet capture from data connections to client devices. The deep packet inspection engine can collect a packet capture of the one or more data packets for the connection (Block 2302). The deep packet inspection engine can set an expiration date for the packet capture indicating when the packet capture can be overwritten in the cloud simple storage system (Block 2304). The deep packet inspection engine can send the packet capture to a cloud simple storage system for storage (Block 2306).

Web Site

The web site is configured as a browser-based tool or direct cooperating app tool for configuring, analyzing, and communicating with the cyber threat defense platform.

Network

A number of electronic systems and devices can communicate with each other in a network environment. The network can include at least one firewall, at least one network switch, multiple computing devices operable by users of the network, a cyber-threat coordinator-component, and a host-based agent. FIG. 24 illustrates in a simplified diagram a networked environment. The network environment has a communications network. The network can include one or more networks selected from an optical network, a cellular network, the Internet, a Local Area Network (“LAN”), a Wide Area Network (“WAN”), a satellite network, a 3^(rd) party ‘cloud’ environment; a fiber network, a cable network, and combinations thereof. In some embodiments, the communications network is the Internet. There may be many server computing systems and many client computing systems connected to each other via the communications network.

The communications network can connect one or more server computing systems selected from at least a first server computing system and a second server computing system to each other and to at least one or more client computing systems as well. The server computing systems can each optionally include organized data structures such as databases. Each of the one or more server computing systems can have one or more virtual server computing systems, and multiple virtual server computing systems can be implemented by design. Each of the one or more server computing systems can have one or more firewalls and similar defenses to protect data integrity.

At least one or more client computing systems for example, a mobile computing device (e.g., smartphone with an Android-based operating system can communicate with the server(s). The client computing system can include, for example, the software application or the hardware-based system in which may be able exchange communications with the first electric personal transport vehicle, and/or the second electric personal transport vehicle. Each of the one or more client computing systems can have one or more firewalls and similar defenses to protect data integrity.

A cloud provider platform may include one or more of the server computing systems. A cloud provider can install and operate application software in a cloud (e.g., the network such as the Internet) and cloud users can access the application software from one or more of the client computing systems. Generally, cloud users that have a cloud-based site in the cloud cannot solely manage a cloud infrastructure or platform where the application software runs. Thus, the server computing systems and organized data structures thereof can be shared resources, where each cloud user is given a certain amount of dedicated use of the shared resources. Each cloud user's cloud-based site can be given a virtual amount of dedicated space and bandwidth in the cloud. Cloud applications can be different from other applications in their scalability, which can be achieved by cloning tasks onto multiple virtual machines at run-time to meet changing work demand. Load balancers distribute the work over the set of virtual machines. This process is transparent to the cloud user, who sees only a single access point.

Cloud-based remote access can be coded to utilize a protocol, such as Hypertext Transfer Protocol (“HTTP”), to engage in a request and response cycle with an application on a client computing system such as a web-browser application resident on the client computing system. The cloud-based remote access can be accessed by a smartphone, a desktop computer, a tablet, or any other client computing systems, anytime and/or anywhere. The cloud-based remote access is coded to engage in 1) the request and response cycle from all web browser based applications, 3) the request and response cycle from a dedicated on-line server, 4) the request and response cycle directly between a native application resident on a client device and the cloud-based remote access to another client computing system, and 5) combinations of these.

In an embodiment, the server computing system can include a server engine, a web page management component, a content management component, and a database management component. The server engine can perform basic processing and operating-system level tasks. The web page management component can handle creation and display or routing of web pages or screens associated with receiving and providing digital content and digital advertisements. Users (e.g., cloud users) can access one or more of the server computing systems by means of a Uniform Resource Locator (“URL”) associated therewith. The content management component can handle most of the functions in the embodiments described herein. The database management component can include storage and retrieval tasks with respect to the database, queries to the database, and storage of data.

In some embodiments, a server computing system can be configured to display information in a window, a web page, or the like. An application including any program modules, applications, services, processes, and other similar software executable when executed on, for example, the server computing system, can cause the server computing system to display windows and user interface screens in a portion of a display screen space. With respect to a web page, for example, a user via a browser on the client computing system can interact with the web page, and then supply input to the query/fields and/or service presented by the user interface screens. The web page can be served by a web server, for example, the server computing system, on any Hypertext Markup Language (“HTML”) or Wireless Access Protocol (“WAP”) enabled client computing system (e.g., the client computing system 802B) or any equivalent thereof. The client computing system can host a browser and/or a specific application to interact with the server computing system. Each application has a code scripted to perform the functions that the software component is coded to carry out such as presenting fields to take details of desired information. Algorithms, routines, and engines within, for example, the server computing system can take the information from the presenting fields and put that information into an appropriate storage medium such as a database (e.g., database). A comparison wizard can be scripted to refer to a database and make use of such data. The applications may be hosted on, for example, the server computing system and served to the specific application or browser of, for example, the client computing system. The applications then serve windows or pages that allow entry of details.

Computing Systems

A computing system can be, wholly or partially, part of one or more of the server or client computing devices in accordance with some embodiments. Components of the computing system can include, but are not limited to, a processing unit having one or more processing cores, a system memory, and a system bus that couples various system components including the system memory to the processing unit. The system bus may be any of several types of bus structures selected from a memory bus or memory controller, a peripheral bus, and a local bus using any of a variety of bus architectures.

The computing system typically includes a variety of computing machine-readable media. Computing machine-readable media can be any available media that can be accessed by computing system and includes both volatile and nonvolatile media, and removable and non-removable media. By way of example, and not limitation, computing machine-readable media use includes storage of information, such as computer-readable instructions, data structures, other executable software or other data. Computer-storage media includes, but is not limited to, RAM, ROM, EEPROM, flash memory or other memory technology, CD-ROM, digital versatile disks (DVD) or other optical disk storage, magnetic cassettes, magnetic tape, magnetic disk storage or other magnetic storage devices, or any other tangible medium which can be used to store the desired information and which can be accessed by the computing device 900. Transitory media, such as wireless channels, are not included in the machine-readable media. Communication media typically embody computer readable instructions, data structures, other executable software, or other transport mechanism and includes any information delivery media.

The system memory includes computer storage media in the form of volatile and/or nonvolatile memory such as read only memory (ROM) and random access memory (RAM). A basic input/output system (BIOS) containing the basic routines that help to transfer information between elements within the computing system, such as during start-up, is typically stored in ROM. RAM typically contains data and/or software that are immediately accessible to and/or presently being operated on by the processing unit. By way of example, and not limitation, the RAM can include a portion of the operating system, application programs, other executable software, and program data.

The drives and their associated computer storage media discussed above, provide storage of computer readable instructions, data structures, other executable software and other data for the computing system.

A user may enter commands and information into the computing system through input devices such as a keyboard, touchscreen, or software or hardware input buttons, a microphone, a pointing device and/or scrolling input component, such as a mouse, trackball or touch pad. The microphone can cooperate with speech recognition software. These and other input devices are often connected to the processing unit through a user input interface that is coupled to the system bus but can be connected by other interface and bus structures, such as a parallel port, game port, or a universal serial bus (USB). A display monitor or other type of display screen device is also connected to the system bus via an interface, such as a display interface. In addition to the monitor, computing devices may also include other peripheral output devices such as speakers, a vibrator, lights, and other output devices, which may be connected through an output peripheral interface.

The computing system can operate in a networked environment using logical connections to one or more remote computers/client devices, such as a remote computing system. The logical connections can include a personal area network (“PAN”) (e.g., Bluetooth®), a local area network (“LAN”) (e.g., Wi-Fi), and a wide area network (“WAN”) (e.g., cellular network), but may also include other networks. Such networking environments are commonplace in offices, enterprise-wide computer networks, intranets and the Internet. A browser application or direct app corresponding with a cloud platform may be resident on the computing device and stored in the memory.

It should be noted that the present design can be carried out on a single computing system and/or on a distributed system in which different portions of the present design are carried out on different parts of the distributed computing system.

Note, an application described herein includes but is not limited to software applications, mobile apps, and programs that are part of an operating system application. Some portions of this description are presented in terms of algorithms and symbolic representations of operations on data bits within a computer memory. These algorithmic descriptions and representations are the means used by those skilled in the data processing arts to most effectively convey the substance of their work to others skilled in the art. An algorithm is here, and generally, conceived to be a self-consistent sequence of steps leading to a desired result. The steps are those requiring physical manipulations of physical quantities. Usually, though not necessarily, these quantities take the form of electrical or magnetic signals capable of being stored, transferred, combined, compared, and otherwise manipulated. It has proven convenient at times, principally for reasons of common usage, to refer to these signals as bits, values, elements, symbols, characters, terms, numbers, or the like. These algorithms can be written in a number of different software programming languages such as Python, C, C+, or other similar languages. Also, an algorithm can be implemented with lines of code in software, configured logic gates in software, or a combination of both. In an embodiment, the logic consists of electronic circuits that follow the rules of Boolean Logic, software that contain patterns of instructions, or any combination of both.

It should be borne in mind, however, that all of these and similar terms are to be associated with the appropriate physical quantities and are merely convenient labels applied to these quantities. Unless specifically stated otherwise as apparent from the above discussions, it is appreciated that throughout the description, discussions utilizing terms such as “processing” or “computing” or “calculating” or “determining” or “displaying” or the like, refer to the action and processes of a computer system, or similar electronic computing device, that manipulates and transforms data represented as physical (electronic) quantities within the computer system's registers and memories into other data similarly represented as physical quantities within the computer system memories or registers, or other such information storage, transmission or display devices.

Many functions performed by electronic hardware components can be duplicated by software emulation. Thus, a software program written to accomplish those same functions can emulate the functionality of the hardware components in input-output circuitry.

While the foregoing design and embodiments thereof have been provided in considerable detail, it is not the intention of the applicant(s) for the design and embodiments provided herein to be limiting. Additional adaptations and/or modifications are possible, and, in broader aspects, these adaptations and/or modifications are also encompassed. Accordingly, departures may be made from the foregoing design and embodiments without departing from the scope afforded by the following claims, which scope is only limited by the claims when appropriately construed. 

What is claimed is:
 1. A method for a cyber threat defense system to differentiate between data flows, comprising: registering, at a traffic manager module of the cyber threat defense system, a connection between one or more devices within a client network to transfer a series of one or more data packets; executing a comparison of features of the connection to a set of interest criteria to determine an interest level for the cyber threat defense system in the connection; applying an interest classifier describing the interest level to the connection based on the comparison; passing the one or more data packets of the connection to a deep packet inspection engine for further examination for cyber threats if the interest classifier indicates interest; and shunting the one or more data packets of the connection away from the deep packet inspection engine if the interest classifier indicates no interest.
 2. The method for the cyber threat defense system of claim 1, further comprising: determining that the connection is not interesting based on the connection being at least one of a long-lived connection, unable to be decrypted within a parameter set for the client device, and within a normal connection pattern.
 3. The method for the cyber threat defense system of claim 1, further comprising: monitoring at least one of a connection length and a payload size for a shunted connection.
 4. The method for the cyber threat defense system of claim 1, further comprising: collecting a set of packet metadata for a shunted connection.
 5. The method for the cyber threat defense system of claim 1, further comprising: identifying a dropped packet in a passthrough connection being processed by the deep packet inspection engine; and shunting the passthrough connection with the dropped packet away from the deep packet inspection engine.
 6. The method for the cyber threat defense system of claim 1, further comprising: severing the connection upon detection by an analyzer module of an anomalous event at the client device.
 7. The method for the cyber threat defense system of claim 6, further comprising: retrieving data about the connection to spoof reset packets.
 8. The method for the cyber threat defense system of claim 1, further comprising: reconnecting a shunted connection to the deep packet inspection engine upon detection by an analyzer module of an anomalous event at the client device.
 9. The method for the cyber threat defense system of claim 8, further comprising: adjusting the set of interest criteria based on the anomalous event.
 10. A non-transitory computer readable medium comprising computer readable code operable, when executed by one or more processing apparatuses in the cyber threat defense system to instruct a computing device to perform the method of claim
 1. 11. A traffic manager module for a cyber threat defense system, comprising: a registration module configured to register a connection between one or more devices within a client network to transmit a series of one or more data packets; a classifier module configured to execute a comparison of features of the connection to a set of interest criteria to determine an interest level for the cyber threat defense system in the connection and to apply an interest classifier describing the interest level to the connection based on the comparison; a deep packet inspection engine configured to examine the one or more data packets of the connection for cyber threats if the interest classifier indicates interest; and a diverter configured to shunt the one or more data packets of the connection away from the deep packet inspection engine if the interest classifier indicates no interest.
 12. The traffic manager module of claim 11, wherein the classifier module is further configured to adjust the set of interest criteria based on the set of host parameters for the client network.
 13. The traffic manager module of claim 12, wherein the set of host parameters are at least one of storage capacity, processing capacity, and network bandwidth.
 14. The traffic manager module of claim 11, wherein the deep packet inspection engine is configured to collect a packet capture of the one or more data packets for the connection.
 15. The traffic manager module of claim 14, wherein further comprising: an offload module configured to send the packet capture to a cloud storage system.
 16. The traffic manager module of claim 15, wherein the offload module is configured to set an expiration date for the packet capture in the cloud storage system indicating when the packet capture can be overwritten.
 17. The traffic manager module of claim 11, wherein the traffic manager module is located at least one of a host-based agent, a virtualized sensor installed on the hypervisor, a centralized physical appliance, and a centralized cloud appliance.
 18. A network, comprising: at least one firewall; at least one network switch; multiple computing devices operable by users of the network; a cyber-threat coordinator-component that includes a probe module configured to collect, from one or more probes deployed to one or more network devices, input data describing network-administrated activity executed by a network device, a cyber threat module configured to identify whether the input data correspond to a cyber threat to the network, and an analyzer module configured to flag a host-based agent for host-based traffic decryption; and a traffic manager module that includes a registration module configured to register a connection between one or more devices on the network to transfer a series of one or more data packets, a classifier module configured to execute a comparison of features of the connection to a set of interest criteria to determine an interest level for the cyber threat defense system in the connection and to apply an interest classifier describing the interest level to the connection based on the comparison, a deep packet inspection engine configured to examine the one or more data packets of the connection for cyber threats if the interest classifier indicates interest and to execute a host-based traffic decryption of the one or more data packets for the connection, and a diverter configured to shunt the one or more data packets of the connection away from the deep packet inspection engine if the interest classifier indicates no interest.
 19. The network of claim 18, wherein the analyzer module of the cyber-threat coordinator-component is configured to determine the host-based agent warrants host-based traffic decryption based on at least one of rarity of endpoint, rarity of timing, rarity of domain, and environment.
 20. The network of claim 18, wherein the deep packet inspection engine of the host-based agent is configured to execute a decryption by at least one of receiving a private key from a third-party agent, uploading a public/private key pair into a centralized appliance associated with a host-based agent, and retrieving a private key from the client network. 